Constant velocity universal joint

Description

[0001] The present invention relates to a constant velocity universal joint for coupling a driving shaft and a driven shaft, to be used, for example, for a driving force-transmitting section of an automobile.

Description of the Related Art:

[0002] A constant velocity universal joint has been hitherto used for a driving force-transmitting section of an automobile in order to transmit a rotary driving force or torque of a driving shaft to respective axles through a driven shaft.

[0003] Such a conventional constant velocity universal joint is based on a technical concept disclosed in Japanese Laid-Open Patent Publication No. 6-123316. A system is adopted in Japanese Laid-Open Patent Publication No. 6-123316, in which a contact surface having a sagital configuration formed on a roller element is allowed to contact with a sagital running surface formed on a recess of an outer member, and an annular shoulder formed on the roller element or a roller support is allowed to abut against a shoulder surface defined on an indentation. Thus the roller element is prevented from tilting in a track.

[0004] Another conventional constant velocity universal joint is based on a technical concept disclosed in Japanese Laid-Open Patent Publication No. 4-282028. A system is adopted in Japanese Laid-Open Patent Publication No. 4-282028, in which a vertical gap is defined inside an outer member. The system includes a roll body for always contacting with a rolling surface defined in the vertical gap through either a contact point A or a contact point B and a contact point C, and a shoulder for regulating displacement of the roll body.

[0005] However, the conventional constant velocity universal joints as described above involve the following disadvantages. Namely, the angle of inclination of the roller element is regulated only by the shoulder surface expanding radially inwardly adjacent to the track. Further, the displacement of the roll body is regulated only by the shoulder. Therefore, it is impossible to sufficiently regulate the angle of inclination of the roller element or the roll body.

[0006] In accordance with the pre-characterizing part of claim 1, GB-A-2 259 557 discloses a constant velocity universal joint (fig. 9a to 9c), in which the second plane section has a convex configuration, while the outer rollers have a linear cross section. Therefore, there is neither a linear movement of the holders of the outer rollers perpendicular to the axial direction, nor is the upper end of each holder capable of abutting flatly against the first plane section. There is always a tilt angle between the upper end of each holder and the first plane section.

[0007] A similar constant velocity universal joint is shown in FR-A-2 668 804. Also in this reference, there are embodiments in which the second plane section is convex, while the outer rollers have a linear cross section. There are additional embodiments in which the second plane section has a linear cross section, while the outer rollers have a convex cross section, so that there is again one contact point between the second plane section and the outer roller.

[0008] DE-C-43 01 207 discloses a constant velocity universal joint having an outer member including grooves, and an inner member with trunnion mounting holders, which carry outer rollers, wherein a second plane section of the guide groove is oriented substantially parallel with respect to the center axis of the trunnion and wherein an outer circumferential surface of the outer rollers has a linear cross section forming an acute angle with respect to said second plane section.

[0009] The object of the present invention is to provide a constant velocity universal joint which makes it possible to smoothly transmit rotational motion from one transmitting shaft to the other transmitting shaft by regulating the angle of inclination of an outer roller.

[0010] This is achieved by the features of claim 1. Preferred embodiments of the invention are defined in the dependent claims.

[0011] In a specific embodiment the present invention provides a constant velocity universal joint which makes it possible to sufficiently and highly accurately regulate the angle of inclination of an outer roller by exerting a plurality of functions on the outer roller in a concerted manner.

[0012] According to the present invention, when an outer roller is inclined at a predetermined angle with respect to a guide groove, a first function to regulate an angle of inclination of the outer roller by means of an upper end of a holder which abuts against a plane section of the guide groove, a second function to regulate the angle of inclination of the outer roller by means of frictional resistance generated when the outer roller is slidably displaced along a rolling surface, and a third function to regulate the angle of inclination of the outer roller by means of a curved section of the outer roller which rolls while making point-to-point contact with an expanded section are exerted respectively in a concerted manner. Thus the angle of inclination of the outer roller with respect to the guide groove is regulated.

[0013] In the present invention as described above, the plurality of the functions are exerted on the outer roller in the concerted manner. Thus the angle of inclination of the outer roller with respect to the guide groove can be regulated sufficiently and highly accurately.

[0014] The above and other objects, features and advantages of the present invention will become more apparent from the following description when taken in conjunction with the accompanying drawings in which a preferred embodiment of the present invention is shown by way of illustrative example.

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] FIG. 1 shows a vertical cross-sectional view illustrating a constant velocity universal joint according to an embodiment of the present invention in a cross section taken along a direction perpendicular to an axis of the constant velocity universal joint.

[0016] FIG. 2 shows a vertical cross-sectional view taken along a line II-II shown in FIG. 1.

[0017] FIG. 3 shows an enlarged view of a part of the constant velocity universal joint shown in FIG. 1.

[0018] FIG. 4 shows an enlarged view of a part of the constant velocity universal joint shown in FIG. 3.

[0019] FIG. 5 illustrates operation of the constant velocity universal joint shown in FIG. 2 in a state in which an outer roller is inclined at a predetermined angle.

[0020] FIG. 6 shows a vertical cross-sectional view illustrating a modified embodiment of a trunnion for constructing the constant velocity universal joint shown in FIG. 1.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0021] In FIG. 1, reference numeral 10 indicates a constant velocity universal joint according to an embodiment of the present invention. The constant velocity universal joint 10 basically comprises a cylindrical outer cup (outer member) 12 integrally coupled to one end of an unillustrated driving shaft and having an opening, and an inner member 16 secured to one end of a driven shaft 14 and accommodated in a hole of the outer cup 12.

[0022] Three guide grooves 18a to 18c are defined on an inner circumferential surface of the outer cup 12. The guide grooves 18a to 18c extend along an axial direction, and they are spaced apart from each other by an angle of 120 degrees respectively. Each of the guide grooves 18a (18b, 18c) is formed with a plane section (first plane section) 20 formed to be flat, and a plane substantially perpendicular to the plane section 20. The guide groove 18a (18b, 18c) has a rolling surface (second plane section) 24 which contacts with an outer circumferential surface of an outer roller 22 described later on.

[0023] An expanded section 28, which protrudes toward a center of a trunnion 26a (26b, 26c) described later on and has a curved and/or flat configuration, is formed at a lower end of the rolling surface 24. The opening of the outer cup 12 is closed by an unillustrated flexible boot.

[0024] As shown in FIG. 1, a ring-shaped boss 30 is externally fitted to the driven shaft 14. The three trunnions 26a (26b, 26c), which expand toward the guide grooves 18a (18b, 18c) and are spaced apart from each other by an angle of 120 degrees about the axial center respectively, are integrally formed on an outer circumferential surface of the boss 30. Each of the trunnions 26a (26b, 26c) is formed to expand in a columnar configuration along a direction substantially perpendicular to the axis of the driven shaft 14. A ring-shaped inner roller 32, which has its outer circumferential surface formed to be a spherical surface, is externally fitted to each of the trunnions 26a (26b, 26c).

[0025] A cylindrical holder 34 is externally fitted to the inner roller 32 The holder 34 is constructed such that an inner circumferential surface of the holder 34 formed to have a linear cross section contacts with the outer circumferential surface of the inner roller 32 formed to have a curved cross section. Therefore, the trunnion 26a (26b, 26c) is slidable along an axial direction of the holder 34 by the aid of the inner roller 32, and it is tiltable within a predetermined angle with respect to the holder 34.

[0026] In another embodiment, it is allowable to use a spherical trunnion 27a (27b, 27c) in which the inner roller 32 and the trunnion 26a (26b, 26c) shown in FIG. 1 are combined into one unit (see FIG. 6). In this embodiment, it is unnecessary to provide the inner roller 32. Therefore, an advantage is obtained in that the number of parts is reduced, and the production cost can be decreased.

[0027] An upper end 36 of the holder 34 protrudes toward the plane section 20 as compared with an upper end of the inner roller 32 so that the upper end 36 of the holder 34 is capable of abutting against and being separated from the plane section 20 of the guide groove 18a (18b, 18c). Namely, the upper end 36 of the holder 34 is positioned, in an ordinary state, to have a slight clearance with respect to the plane section 20 of the guide groove 18a (18b, 18c). Further, the upper end 36 of the holder 34 is formed to abut against the plane section 20 when the driving shaft or the driven shaft 14 is relatively inclined at a predetermined angle.

[0028] The outer roller 22 is externally fitted to an outer circumferential section of the holder 34 through a plurality of needle bearings 38. The outer roller 22 has its outer circumferential surface with a cross section formed to be linear corresponding to the cross-sectional configuration of the guide groove 18a (18b, 18c). The respective needle bearings 38 and the outer roller 22 are held by a set of circlips 40a, 40b and washers 42a, 42b fitted to annular grooves of the holder 34. It is possible to hold the needle bearings 38 and the outer roller 22 only by using the circlips 40a, 40b without using the washers 42a, 42b.

[0029] The outer circumferential surface of the outer roller 22 makes surface-to-surface contact with the rolling surface 24 of the guide groove 18a (18b, 18c). Thus the outer roller 22 is slidable in its axial direction (in a direction indicated by an arrow X in FIG. 3). Moreover, the outer roller 22 is rollable laterally (in a direction indicated by an arrow Y in FIG. 2) along the rolling surface 24. Further, the outer roller 22 has, at its lower end, a curved section 44 which is formed to have a circular arc-shaped cross section. In an ordinary state, the curved section 44 makes point-to-point contact with the expanded section 28 at a contact point A (see FIG. 4).

[0030] Although the expanded section 28 of the outer cup 12 and the curved section 44 of the outer roller 22 may be formed to have the same radius of curvature, a different radius of curvature can be adopted in the expanded section 28 of the outer cup 12 and the curved section 44 of the outer roller. Radii of curvature set as different from each other achieve advantages such that degrees of freedom for designing increase and they are processed easily. Further, where the outer roller 22 has the curved section 44, the expanded section 28 may adopt flat shape. Stated otherwise, the expanded section 28 may adopt the flat shape at the contact point A. Still further, the expanded section 28 may adopt the shape in combination of flat with curved one.

[0031] The constant velocity universal joint 10 according to the embodiment of the present invention is basically constructed as described above. Now, the operation, function, and effect of the constant velocity universal joint 10 will be explained.

[0032] When the unillustrated driving shaft is rotated, its rotary driving force or torque is transmitted to the inner member 16 through the outer cup 12. Accordingly, the driven shaft 14 is rotated in a predetermined direction by the aid of the trunnions 26a to 26c.

[0033] Namely, the rotary driving force of the outer cup 12 is transmitted to the outer rollers 22 which are displaceable along the guide grooves 18a (18b, 18c). The force is further transmitted to the holders 34 held by the outer rollers 22 through the needle bearings 38, and the force is transmitted to the trunnions 26a (26b, 26c) through the inner rollers 32. Thus the driven shaft 14, which is engaged with the trunnions 26a (26b, 26c), is rotated.

[0034] In this operation, if the unillustrated driving shaft or the driven shaft 14 is inclined, the outer rollers 22 roll along the guide grooves 18a to 18c. Accordingly, the velocity of rotation of the driving shaft is not affected by the angle of inclination of the driven shaft 14 with respect to the outer cup 12, and the force is always transmitted to the driven shaft 14 at a constant velocity of rotation.

[0035] In the present invention, if the outer roller 22 is inclined at a predetermined angle with respect to the guide groove 18a (18b, 18c) as shown in FIG. 5, the following functions are exerted. Namely, a first function to regulate the angle of inclination of the outer roller 22 by means of the upper end 36 of the holder 34 which abuts against the plane section 20 of the guide groove 18a (18b, 18c), a second function to regulate the angle of inclination of the outer roller 22 by means of frictional resistance generated when the outer roller 22 is slidably displaced vertically (in the direction indicated by the arrow X) along the guide groove 18a (18b, 18c), and a third function to regulate the angle of inclination of the outer roller 22 by means of the curved section 44 of the outer roller 22 which rolls along the expanded section 28 formed at the lower end of the guide groove 18a (18b, 18c) while making point-to-point contact are exerted respectively in a concerted manner. Thus the angle of inclination of the outer roller 22 with respect to the guide groove 18a (18b, 18c) is regulated.

[0036] As described above, the first to third functions are exerted on the outer roller 22 in the concerted manner. Thus the angle of inclination of the outer roller 22 with respect to the guide groove 18a (18b, 18c) can be regulated sufficiently and highly accurately.

[0037] As a result, the rotational motion provided on the side of the unillustrated driving shaft can be smoothly transmitted to the side of the driven shaft.

Claims

1. A constant velocity universal joint comprising cylindrical outer member (12) coupled to one transmitting shaft and having on its inner circumferential surface, a plurality of guide grooves (18a to 18c) spaced apart from each other by a predetermined spacing and exending along an axial direction (Y) and an inner member (16) comprising trunnions (26a to 26c) coupled to the other transmitting shaft (14) and inserted into an opening inner space of said outer member (12), each of said guide grooves (18a to 18c) having a first plane section (20) and a second plane section (24);
   outer rollers (22) each having an outer circumferential cylindrical surface having a linear cross section corresponding to said second plane section (24), each of said outer rollers (22) being displaceable along said second plane section (24);
   holders (34) for holding said outer rollers (22) on said trunnions (26a to 26c), each of said holders (34) having an upper end (36) capable of abutting against or being separated from said first plane section (20);
   expanded sections (28) formed adjacent to said second plane sections (24), each of said expanded sections (28) having a curved and/or a flat configuration and protruding toward said trunnions (26a to 26c); and
   curved sections (44) each formed in a curved configuration at one end in an axial direction of said outer roller (22), and making point-to-point contact with each of said expanded sections (28),
   characterized in that
   said second plane section (24) has a linear cross section perpendicular to said first plane section (20), that each of the outer rollers (22) is displaceable along said second plane section in a direction (X) substantially perpendicular to said axial direction , and that the upper end of each of said holders (34) is capable of abutting against and being separated from said first plane section by linear displacement of the outer roller toward and away from said first plane section in said perpendicular direction.

2. The constant velocity universal joint according to claim 1, wherein said outer roller (22) is rollable and displaceable along said axial direction (y) of said second plane section (24).

3. The constant velocity universal joint according to claim 1, wherein said expanded section (28) and said curved section (44) are formed to make contact at one point.

4. The constant velocity universal joint according to claim 1, wherein said trunnion (26a to 26c) is formed to have a columnar configuration, and an inner roller (32) having a spherical surface is interposed between said trunnion (26a to 26c) and said holder (34) for surrounding said trunnion (26a to 26c).

5. The constant velocity universal joint according to claim 4, wherein said columnar trunnion and said inner roller having said spherical surface are integrated with each other to provide a spherical trunnion (27a to 27c).

6. The constant velocity universal joint according to claim 1, wherein said outer roller (22) is fastened to said holder by fastening members engaged with said holder (34), said fastening members comprising circlips (40a, 40b) fitted to said holder (34).

7. The constant velocity universal joint according to claim 6, wherein said fastening members comprise said circlips (40a, 40b) and washers (42a, 42b) fitted to said holder (34).

8. The constant velocity universal joint according to claim 3, wherein said expanded section (28) and said curved section (44), which make said point-to-point contact with each other, are formed to have different radii of curvature respectively.

9. The constant velocity universal joint according to claim 3, wherein said expanded section (28) has a flat configuration and said curved section (44) has a curved configuration, which make said point-to-point contact with each other.

10. The constant velocity universal joint according to claim 1, wherein when said outer roller (22) is inclined at a predetermined angle with respect to said guide groove (18a to 18c), a first function to regulate said angle of inclination of said outer roller (22) by means of said upper end (36) of said holder (34) which abuts against said first plane section (20), a second function to regulate said angle of inclination of said outer roller (22) by means of frictional resistance genereated when said outer roller (22) is slidably displaced in a direction substantially perpendicular to said axis of said guide groove (18a to 18c), and a third function to regulate said angel of inclination of said outer roller (22) by means of said curved section (44) of said outer roller (22) which rolls while making said point-to-point contact along said expanded section (28) at a lower end of said guide groove (18a to 18c) are exerted on said outer roller (22) respectively; and
   said first to third functions are exerted in a concerted manner respectively for regulating said angle of inclination of said outer roller (22) with respect to said guide groove (18a to 18c) is regulated.

Ansprüche

1. Homokinetisches Universalgelenk, umfassend ein zylindrisches Außenteil (12), das an eine Übertragungswelle gekoppelt ist und an seiner inneren Umfangsfläche eine Mehrzahl von Führungsnuten (18a bis 18c) aufweist, die voneinander durch einen vorbestimmten Abstand beabstandet sind und sich entlang einer axialen Richtung (Y) erstrecken, und ein Innenteil (16) mit Drehzapfen (26a bis 26c), das an die andere Übertragungswelle (14) gekoppelt ist und in einen offenen Innenraum des Außenteils (12) eingesetzt ist, wobei jede der Führungsnuten (18a bis 18c) eine erste Ebene (20) und eine zweite Ebene (24) aufweist;
Außenrollen (22), jeweils mit einer äußeren Umfangs-Zylinderfläche mit geradlinigem Querschnitt entsprechend der zweiten Ebene (24), wobei jede der Außenrollen (22) entlang der zweiten Ebene (24) verlagerbar ist;
Halter (34) zum Halten der Außenrollen (22) auf den Drehzapfen (26a bis 26c), wobei jeder der Halter (34) ein oberes Ende (36) besitzt, welches in Anlage an die erste Ebene (20) bringbar oder von ihr abrückbar ist;
erweiterte Abschnitte (28), die benachbart zu der zweiten Ebene (24) ausgebildet sind, wobei jeder der erweiterten Abschnitte (28) eine gekrümmte und/oder eine flache Konfiguration aufweist und in Richtung der Drehzapfen (26a bis 26c) vorragt; und
Kurvenabschnitte (44), jeweils in Kurvenform an einem Ende in axialer Richtung der Außenrolle (22) gebildet und mit jedem der erweiterten Abschnitte (28) punktkontaktbildend,
dadurch gekennzeichnet, daß
die zweite Ebene (24) einen geradlinigen Querschnitt rechtwinklig zu der ersten Ebene (20) aufweist, daß jede der Außenrollen (22) entlang der zweiten Ebene in einer Richtung (X) etwa rechtwinklig zu der axialen Richtung verlagerbar ist, und daß das obere Ende jedes der Halter (34) im Stande ist, an der ersten Ebene anzuschlagen und von dieser abzurücken durch lineare Verlagerung der Außenrolle in Richtung auf die erste Ebene zu bzw. von ihr weg in der rechtwinkligen Richtung.

2. Universalgelenk nach Anspruch 1, dadurch gekennzeichnet, daß die Außenrolle (22) entlang der axialen Richtung (y) der zweiten Ebene (24) abrollbar und verlagerbar ist.

3. Universalgelenk nach Anspruch 1, bei dem der erweiterte Abschnitt (28) und der Kurvenabschnitt (44) derart geformt sind, daß sie Kontakt an einem Punkt haben.

4. Universalgelenk nach Anspruch 1, bei dem der Drehzapfen (26a bis 26c) so ausgebildet ist, daß er einen säulenförmigen Aufbau hat, und daß eine Innenrolle (32) mit einer Kugeloberfläche zwischen dem Drehzapfen (26a bis 26c) und dem Halter (34) in den Drehzapfen (26a bis 26c) umgebender Weise angeordnet ist.

5. Universalgelenk nach Anspruch 4, bei dem der säulenförmige Drehzapfen und die Innenrolle die Kugelfläche in integrierter Form gemeinsam aufweisen, um einen kugelförmigen Drehzapfen (27a bis 27c) zu bilden.

6. Universalgelenk nach Anspruch 1, bei dem die Außenrolle (22) an dem Halter durch Befestigungsmittel befestigt ist, die mit dem Halter (34) in Eingriff sind, wobei die Befestigungsmittel in den Halter (34) eingepaßte Sprengringe (40a, 40b) aufweisen.

7. Universalgelenk nach Anspruch 6, bei dem die Befestigungsmittel die Sprengringe (40a, 40b) sowie an den Halter (34) angesetzte Beilagscheiben (42a, 42b) aufweisen.

8. Universalgelenk nach Anspruch 3, bei dem der erweiterte Abschnitt (28) und der Kurvenabschnitt (44), die miteinander Punktkontakt bilden, so ausgebildet sind, daß sie unterschiedliche Krümmungsradien besitzen.

9. Universalgelenk nach Anspruch 3, bei dem der erweiterte Abschnitt (28) eine flache Konfiguration besitzt und der Kurvenabschnitt (44) eine gekrümmte Konfiguration besitzt, die miteinander den Punktkontakt bilden.

10. Universalgelenk nach Anspruch 1, bei dem, wenn die Außenrolle (22) unter einem vorbestimmten Winkel bezüglich der Führungsnut (18a bis 18c) geneigt ist, auf die Außenrolle (22) eine erste Funktion zum Regulieren des Neigungswinkels der Außenrolle (22) mit Hilfe des oberen Endes (36) des Halters (34), das gegen die erste Ebene (20) anstößt, eine zweite Funktion zum Regulieren des Neigungswinkels der Außenrolle (22) mittels des Reibungswiderstands, erzeugt bei der gleitenden Verlagerung der Außenrolle (22) in eine Richtung etwa rechtwinklig zur Achse der Führungsnut (18a bis 18c), und eine dritte Funktion zum Regulieren des Neigungswinkels der Außenrolle (22) mittels des Kurvenabschnitts (44) der Außenrolle (22), der bei Punktkontakt entlang dem erweiterten Abschnitt (28) an einem unteren Ende der Führungsnut (18a bis 18c) rollt, ausgeübt werden; und wobei die erste bis dritte Funktion in konzertierter Weise ausgeübt werden, um den Neigungswinkel der Außenrolle (22) bezüglich der Führungsnut (18a bis 18c) zu regulieren.

Revendications

1. Joint homocinétique comportant un élément extérieur cylindrique (12) relié à un arbre de transmission et ayant sur sa surface circonférentielle interne plusieurs rainures de guidage (18a à 18c) espacées l'une de l'autre d'un espacement prédéterminé et s'étendant le long d'une direction axiale (Y) et un élément intérieur (16) comportant des tourillons (26a à 26c) reliés à l'autre arbre de transmission (14) et insérés dans un espace interne ouvert dudit élément extérieur (12), chacune des rainures de guidage (18a à 18c) ayant une première section plane (20) et une deuxième surface plane (24);
   des rouleaux extérieurs (22) ayant chacun une surface cylindrique circonférentielle externe ayant une section linéaire correspondant à ladite deuxième surface plane (24), chacun desdits rouleaux extérieurs (22) pouvant être déplacé le long de ladite deuxième surface plane (24);
   des supports (34) destinés à maintenir lesdits rouleaux extérieurs (22) sur lesdits tourillons (26a à 26c), chacun desdits supports (34) ayant une extrémité supérieure (36) capable de buter contre ou être séparée de ladite première section plane (20);
   des sections élargies (28) formées de façon adjacente aux dites deuxièmes surfaces planes (24), chacune desdites sections élargies (28) ayant une configuration courbe et/ou plate et dépassant vers lesdits tourillons (26a à 26c); et
   des sections courbes (44) formées chacune dans une configuration courbe à une extrémité dans une direction axiale dudit rouleau extérieur (22), et réalisant un contact ponctuel avec chacune desdites sections élargies (28),
   caractérisé en ce que
   ladite deuxième surface plane (24) a une section linéaire perpendiculaire à ladite première section plane (20), en ce que chacun des rouleaux extérieurs (22) peut être déplacé le long de ladite deuxième section plane dans une direction (X) sensiblement perpendiculaire à ladite direction axiale, et en ce que l'extrémité supérieure de chacun desdits supports (34) est capable de buter contre et être séparée de ladite première section plane par un déplacement linéaire du rouleau extérieur vers et à l'écart de ladite première section plane dans ladite direction perpendiculaire.

2. Joint homocinétique selon la revendication 1, dans lequel ledit rouleau extérieur (22) peut rouler et être déplacé le long de ladite direction axiale (Y) de ladite deuxième surface plane (24).

3. Joint homocinétique selon la revendication 1, dans lequel ladite section élargie (28) et ladite section courbe (44) sont formées afin de réaliser un contact en un point.

4. Joint homocinétique selon la revendication 1, dans lequel ledit tourillon (26a à 26c) est formé afin d'avoir une configuration en colonne, et un rouleau intérieur (32) ayant une surface sphérique est interposé entre ledit tourillon (26a à 26c) et ledit support (34) afin d'entourer ledit tourillon (26a à 26c).

5. Joint homocinétique selon la revendication 4, dans lequel ledit tourillon en colonne et ledit rouleau interne ayant ladite surface sphérique sont intégrés l'un à l'autre afin de procurer un tourillon sphérique (27a à 27c).

6. Joint homocinétique selon la revendication 1, dans lequel ledit rouleau extérieur (22) est fixé sur ledit support par des éléments de fixation engagés avec ledit support (34), lesdits éléments de fixation comportant des anneaux élastiques (40a, 40b) montés sur ledit support (34).

7. Joint homocinétique selon la revendication 6, dans lequel lesdits éléments de fixation comprennent lesdits anneaux élastiques (40a, 40b) et des rondelles (42a, 42b) montées sur ledit support (34).

8. Joint homocinétique selon la revendication 3, dans lequel ladite section élargie (28) et ladite section courbe (44), qui réalisent ledit contact ponctuel l'une avec l'autre, sont formées afin d'avoir des rayons de courbure différents de manière respective.

9. Joint homocinétique selon la revendication 3, dans lequel ladite section élargie (28) a une configuration plate et ladite section courbe (44) a une configuration courbe, qui réalisent ledit contact ponctuel l'une avec l'autre.

10. Joint homocinétique selon la revendication 1, dans lequel, lorsque ledit rouleau extérieur (22) est incliné avec un angle prédéterminé par rapport à ladite rainure de guidage (18a à 18c), une première fonction de régulation dudit angle d'inclinaison dudit rouleau extérieur (22) au moyen de ladite extrémité supérieure (36) dudit support (34) qui bute contre ladite première section plane (20), une deuxième fonction de régulation dudit angle d'inclinaison dudit rouleau extérieur (22) au moyen d'une résistance de friction générée lorsque ledit rouleau extérieur (22) est déplacé de façon coulissante dans une direction sensiblement perpendiculaire au dit axe de ladite rainure de guidage (18a à 18c), et une troisième fonction de régulation dudit angle d'inclinaison dudit rouleau extérieur (22) au moyen de ladite section courbe (44) dudit rouleau extérieur (22) qui roule tout en réalisant ledit contact ponctuel le long de ladite section élargie (28) au niveau d'une extrémité inférieure de ladite rainure de guidage (18a à 18c) sont exercées sur ledit rouleau extérieur (22) respectivement; et
   lesdites première à troisième fonctions sont exercées d'une manière concertée respectivement afin de réguler ledit angle d'inclinaison dudit rouleau extérieur (22) par rapport à ladite rainure de guidage (18a à 18c).

Drawing